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Process design and evaluation of butanol production from lignocellulosic biomass
Presented at Bioenergy2009 4th International Bioenergy Conference and Exibition on 31st August to 4th September 2009
Jyväskylä - Finland
C.M. Daza Montaño
ECN-L--09-117 September 2009
PROCESS DESIGN AND EVALUATION OF BUTANOL PRODUCTION
FROM LIGNOCELLULOSIC BIOMASS
Claudia Daza Montaño
2 8-9-2009
Presentation Outline
•Why Butanol?
•ABE (acetone, butanol, ethanol) fermentation background and state of
the art
•Developed conceptual process design
•Economic evaluation
•Environmental Impact assessment (LCA)
•Conclusions
3 8-9-2009
BUTANOL (C4
H9
OH): Bulk chemical and fuel
Butanol
is better biofuel
than ethanol due to its more favorable chemical/physical
properties. But even more valuable as chemical
Properties 1-ButanolC4
H9
OHEthanolC2
H5
OHLHV (MJth/kg) 33 27
Solubility (ml/100 ml H2
O) 9 miscibleVapor pressure (mmHg) 5 44
Flash point (oC) 37 15
Butanol can be shipped and distributed through existing pipelines and filling stations
Butanol can be blended with diesel and with gasoline
Butanol is a widely used solvent in industry
4 8-9-2009
Acetone-butanol-ethanol (ABE) fermentationClostridia strains A:B:E≈
3:6:1 wt.
Sugars and starch
1920 1950 2008 2015
Traditional fermentation Petrochemicals ABE revivalChemicals
Biofuels •USA•Canada•South Africa•China•Japan•URSS•Others
Pict. source: Jones, D. Clostridium
X Workshop
•DuPont & BP in UK•USA•China•Brazil•Others
5 8-9-2009
Challenges and research on butanol
fermentation
expensive DSP
butanol toxicity (10 gr/l)
low solvent yields
dilute product streams
low productivity
high cost of raw material
Metabolic and Genetic engineering
•
Broad substrate range –
agricultural and food industry residues
•
Solvent tolerant strains•
Thermophilic
strains•
Selective product formation
Process technology
•Upstream: Pre-treatment and hydrolysis•Fermentation configuration •In Situ Product Removal ISPR•DSP and process integration
6 8-9-2009
Definition of process designed
•Plant capacity 100 kton/year bio-butanol (167 kton/year ABE)
•Lignocellulosic feedstock Wheat straw
Input 1416 kton/year (d.m)
Cost: 31€/ton (d.m.)
•Mode of operation Continuous
•In situ product removal technique Gas stripping
7 8-9-2009
ABE fermentation parameters
Compound Formula wt %
Sugars CH2
O -Acetone C3
H6
O 9Butanol C4
H9
OH 18Ethanol C2
H5
OH 3
Acetic acid CH3
COOH 1.5Butyric acid C4
H8
O2 1.5Hydrogen H2 1.6
Microbial cells CH1.8
O0.5
N0.2 12.7
Carbon dioxide CO2 49.7
Acidogenic
PhaseH2
production
• Wild type -
Anaerobic bacteria
•Saccharolytic: C6 (glucose)
and C5 (xylose) and sugar polymers (starch, xylan)
•Typical yield: 0.3 kg A.B.E/kgsugar
with 3:6:1mass ratio
Solvent-producing Clostridia beijerinckii
NACIMB 8052
8 8-9-2009
Product recovery
Fermentation with membrane
cell retention
CO2ABE
Water
Hydrolisate
Gas recycle
Condenser-50 oC
ABEWater
Gas
Decanter
WaterABE
ABE Water
Purge
Gas stripping advantages:
•Simple technology
•Selective removal of volatile compounds
•Use of fermentation off gas (CO2
)
•No toxicity to cells
Product Removal (ISPR) required to optimize fermentation productivity
Technology Efficiency State of development Scale Capital cost Operating
costTechnology
status
Distillation High Complete Commercial Med High Commercial
Gas Stripping Medium Research Lab High High Research
Solvent Extraction High Research Lab Med Med Research
Pervaporation High Development Pilot High High Research
Adsorption High Research Commercial High Low Research
9 8-9-2009
Main process sections
Anaerobic Digestion 2
Steam Turbine
Flue GasesDigestate
Water, N
Combustion
H2
SIZE REDUCTION+
MILD ACIDPRETREATMENT
ENZYMATIC HYDROLYSIS
+ SOLIDS-LIQUID
SEPARATION
ABEFERMENTATION
+ IN SITU PRODUCT REMOVAL (ISPR)
PRODUCT UPGRADING
RESIDUES TREATMENT
CHP 1 HEAT & POWER GENERATION
Water
Ashes
CHP 2 HEAT & POWER GENERATION
Air
Anaerobic Digestion 1
Digestate
H&P
Butanol
Water
Ethanol
Acetone
Gas Turbine
Gas purge
Flue gases
H&PWhat straw
Nutrients
Water
Enzymes
Lime
Sulph. acid
CH4
CO2
10 8-9-2009
Overall mass & energy balanceInputs Kton/year Value MW
Wheat straw (d.w., 9 wt% ash) 1416 835*Heat demand 196Electricity demand 61Total input 1091
OutputsAcetone 50
181 *Butanol 100Ethanol 17Heat generation in CHP’s 431Electricity generation in CHP’s 196Total output 808Net heat surplus 235Net electricity surplus 136
%38)(feedstockinput Energy
outputy ElectricitABEin content Energy efficiencyEnergy =+
=
*(LHV basis)
•Process
energy
demand
(steam
and electricity) fully
covered
+ large
electricity
export•Room for
improvement
via heat integration•Surplus heat could
be
used
for
sterilization
or
for
cooling
generation
via Absorption
Refrigeration
Plant
11 8-9-2009
Total production cost
Costs €/TonABE
Raw materials 421
Utilities 5 Labor 21 Maintenance 110 Others 71
Taxes 30
Capital charge 204 Total gross 862
Total-electricity* sales 408
Production cost distribution
Capital charge24%
Utilities1%
Labour2%
Maintenance13%
Others8%
Taxes4%
Water1%
Nutrients1%
Sulphuric acid0%
Lime0%
Straw30%
Enzymes16%
Raw materials
* 0.07 €/kWh
12 8-9-2009
PRODUCT
CHEMICALS PRODUCTION ANNUAL SALES PRODUCT VALUE
Selling Price €/Ton Kton/year M€/year %
Acetone 571 50 28 20
Butanol 929 100 93 68
Ethanol 857 17 15 12
Total ABE (3:6:1 wt) 814 167 136 100
Product sales revenues
Internal
Rate
of Return (IRR) = 9,6%
13 8-9-2009
Sensitivity analysis on Internal Rate of Return (IRR)
Sensitivity analysis of main cost on IRR
-5%
0%
5%
10%
15%
20%
25%
30%
35%
40%
-60% -40% -20% 0% 20% 40% 60%
variation (%)
IRR
ABE sale price Capital cost Raw materials price Electriciy output
Total ABE sales
as chemicals: 136 M€/yearIRR=9,6%
Product sales
Capital cost
Raw materials cost
Electricity output
PRODUCTS LHV (MJth/kg)FUELS CHEMICALS
Fuel value €/Ton* Market Price €/TonTotal ABE (3:6:1 wt) 31 440 814
*0.015 €/MJth
↑Butanolratio in ABE mixture
14 8-9-2009
Life Cycle Analysis LCA
The goals of the screening LCA are to assess the environmental impacts of ABE production from
straw, in a “cradle to gate”
analysis and to compare these impacts with those of ABE petrol-based
production and with those of gasoline production.
Software: SimaPro
(version 7) www.pre.nl
Goal & scopedefinition
Impactassessment
Inventoryanalysis
Interpretation
Goal & scopedefinition
Impactassessment
Inventoryanalysis
Interpretation
Life Cycle Assessment framework, with different steps of LCA and
their interactions according to ISO standards
15 8-9-2009
Inventory analysis and impact assessment
CHP’s Flue Gases
AshesAir
Butanol
Water
Ethanol
Acetone
Gas purge
Wheat straw
Nutrients N, P
Water
Enzymes
Lime
Sulph. acid
WHEAT STRAW TO ABE PROCESS
Wheatproduction
(allocation 7%)
Grain (average allocation 93%)
Electricity
Process emissions
Ecoinvent databaseFunctional unit 1 MJ ABE
=0.032 kg ABE
Impact categories•Abiotic depletion•Global warming•Ozone layer depletion•Human toxicity•Fresh water aquatic ecotoxicity•Marine aquatic ecotoxicity•Terrestrial ecotoxicity•Photochemical oxidation•Acidification•Eutrophication
CML method (Centrum voor Milieukunde Leiden (CML)
16 8-9-2009
Comparison ABE from wheat straw with gasoline and with petrochemical ABE
-6,E-14
-4,E-14
-2,E-14
0,E+00
2,E-14
4,E-14
6,E-14
8,E-14
1,E-13
Abiotic depletion Acidif ication Eutrophication Global w arming(GWP100)
Ozone layerdepletion (ODP)
Human toxicity Fresh w ateraquatic ecotox.
Marine aquaticecotoxicity
Terrestrialecotoxicity
Photochemicaloxidation
Nor
mal
izat
ion
Straw to ABE Gasoline ABE from petrol Functional unit: 1 MJ
Electricity output
Process emissions
Enzymes &Nutrients
Wheat Straw
Normalization set: West Europe, 1995
17 8-9-2009
Overall conclusions and recommendations
Wheat Straw to ABE as chemicals = CLOSE TO be economically competitive.
o
Raw materials are the major cost driver
Increase of butanol ratio to A:E produced improves energy efficiency and economics
Environmental performance: straw-ABE better than petrol-based ABE
o
Residues conversion into heat and electricity are a key parameter
o
Major environmental impacts: eutrophication
o
Recovery of nutrients and production of useful by-products would improve LCA
OPTION: Retrofit existing ethanol plants for butanol production
18 8-9-2009
AcknowledgementProject partner: Agrotechnology
& Food Sciences Group. Wageningen
University & Research Centre WUR
This work was supported by the Dutch Ministry of Economic Affairs through the program EOS (Subsidy for Research on Energy), and partly financed by SenterNovem. www.senternovem.nl/eos
Claudia M. Daza Montañ[email protected] website: www.biobased.nl/eosbiobutanol
Thank
for
your
attention